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Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts

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Zeitschriftentitel: International Journal of Chemical Reactor Engineering
Personen und Körperschaften: Sehabiague, Laurent, Morsi, Badie I.
In: International Journal of Chemical Reactor Engineering, 11, 2013, 1, S. 309-330
Format: E-Article
Sprache: Unbestimmt
veröffentlicht:
Walter de Gruyter GmbH
Schlagwörter:
General Chemical Engineering
author_facet Sehabiague, Laurent
Morsi, Badie I.
Sehabiague, Laurent
Morsi, Badie I.
author Sehabiague, Laurent
Morsi, Badie I.
spellingShingle Sehabiague, Laurent
Morsi, Badie I.
International Journal of Chemical Reactor Engineering
Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
General Chemical Engineering
author_sort sehabiague, laurent
spelling Sehabiague, Laurent Morsi, Badie I. 1542-6580 2194-5748 Walter de Gruyter GmbH General Chemical Engineering http://dx.doi.org/10.1515/ijcre-2012-0017 <jats:title>Abstract</jats:title> <jats:p>A user-friendly simulator based on a comprehensive computer model for slurry bubble column reactor (SBCR) was used to predict the performance of a conceptual commercial-scale (9-m ID and 50-m height) SBCR for Fischer–Tropsch (F–T) synthesis. Novel correlations for predicting the hydrodynamic and mass transfer parameters; a new relationship between the axial dispersion of large gas bubbles and their average diameter; and up to ten different kinetic rate expressions available in the literature for iron and cobalt-based catalysts were included in the simulator. The effects of operating conditions, including catalyst concentration, pressure, temperature, H<jats:sub>2</jats:sub>/CO ratio, and superficial gas velocity on the SBCR performance were predicted using the simulator for both types of catalysts. The predictions showed that the performance of the reactor was strongly dependent on the type of catalyst and the kinetic rate expression used.</jats:p> Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts International Journal of Chemical Reactor Engineering
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series International Journal of Chemical Reactor Engineering
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title Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_unstemmed Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_full Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_fullStr Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_full_unstemmed Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_short Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_sort modeling and simulation of a fischer–tropsch slurry bubble column reactor using different kinetic rate expressions for iron and cobalt catalysts
topic General Chemical Engineering
url http://dx.doi.org/10.1515/ijcre-2012-0017
publishDate 2013
physical 309-330
description <jats:title>Abstract</jats:title> <jats:p>A user-friendly simulator based on a comprehensive computer model for slurry bubble column reactor (SBCR) was used to predict the performance of a conceptual commercial-scale (9-m ID and 50-m height) SBCR for Fischer–Tropsch (F–T) synthesis. Novel correlations for predicting the hydrodynamic and mass transfer parameters; a new relationship between the axial dispersion of large gas bubbles and their average diameter; and up to ten different kinetic rate expressions available in the literature for iron and cobalt-based catalysts were included in the simulator. The effects of operating conditions, including catalyst concentration, pressure, temperature, H<jats:sub>2</jats:sub>/CO ratio, and superficial gas velocity on the SBCR performance were predicted using the simulator for both types of catalysts. The predictions showed that the performance of the reactor was strongly dependent on the type of catalyst and the kinetic rate expression used.</jats:p>
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author Sehabiague, Laurent, Morsi, Badie I.
author_facet Sehabiague, Laurent, Morsi, Badie I., Sehabiague, Laurent, Morsi, Badie I.
author_sort sehabiague, laurent
container_issue 1
container_start_page 309
container_title International Journal of Chemical Reactor Engineering
container_volume 11
description <jats:title>Abstract</jats:title> <jats:p>A user-friendly simulator based on a comprehensive computer model for slurry bubble column reactor (SBCR) was used to predict the performance of a conceptual commercial-scale (9-m ID and 50-m height) SBCR for Fischer–Tropsch (F–T) synthesis. Novel correlations for predicting the hydrodynamic and mass transfer parameters; a new relationship between the axial dispersion of large gas bubbles and their average diameter; and up to ten different kinetic rate expressions available in the literature for iron and cobalt-based catalysts were included in the simulator. The effects of operating conditions, including catalyst concentration, pressure, temperature, H<jats:sub>2</jats:sub>/CO ratio, and superficial gas velocity on the SBCR performance were predicted using the simulator for both types of catalysts. The predictions showed that the performance of the reactor was strongly dependent on the type of catalyst and the kinetic rate expression used.</jats:p>
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physical 309-330
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publisher Walter de Gruyter GmbH
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series International Journal of Chemical Reactor Engineering
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spelling Sehabiague, Laurent Morsi, Badie I. 1542-6580 2194-5748 Walter de Gruyter GmbH General Chemical Engineering http://dx.doi.org/10.1515/ijcre-2012-0017 <jats:title>Abstract</jats:title> <jats:p>A user-friendly simulator based on a comprehensive computer model for slurry bubble column reactor (SBCR) was used to predict the performance of a conceptual commercial-scale (9-m ID and 50-m height) SBCR for Fischer–Tropsch (F–T) synthesis. Novel correlations for predicting the hydrodynamic and mass transfer parameters; a new relationship between the axial dispersion of large gas bubbles and their average diameter; and up to ten different kinetic rate expressions available in the literature for iron and cobalt-based catalysts were included in the simulator. The effects of operating conditions, including catalyst concentration, pressure, temperature, H<jats:sub>2</jats:sub>/CO ratio, and superficial gas velocity on the SBCR performance were predicted using the simulator for both types of catalysts. The predictions showed that the performance of the reactor was strongly dependent on the type of catalyst and the kinetic rate expression used.</jats:p> Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts International Journal of Chemical Reactor Engineering
spellingShingle Sehabiague, Laurent, Morsi, Badie I., International Journal of Chemical Reactor Engineering, Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts, General Chemical Engineering
title Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_full Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_fullStr Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_full_unstemmed Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_short Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
title_sort modeling and simulation of a fischer–tropsch slurry bubble column reactor using different kinetic rate expressions for iron and cobalt catalysts
title_unstemmed Modeling and Simulation of a Fischer–Tropsch Slurry Bubble Column Reactor Using Different Kinetic Rate Expressions for Iron and Cobalt Catalysts
topic General Chemical Engineering
url http://dx.doi.org/10.1515/ijcre-2012-0017